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营养不良小鼠脊神经根中施万细胞鞘的异常。

Abnormalities in Schwann cell sheaths in spinal nerve roots of dystrophic mice.

作者信息

Stirling C A

出版信息

J Anat. 1975 Feb;119(Pt 1):169-80.

PMID:1133086
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1231626/
Abstract

Dorsal and ventral spinal roots at cervical, thoracic, lumbar and sacral levels in dystrophic, dy/dy, mice of both 129/ReJ and C57Bl/6J phenotypes showed a complete lack of Schwann cell sheaths of any sort around the majority of their nerve fibres. This condition, termed amyelination, is more extensive (up to 1-5 cm in length) in the longer lumbar and sacral roots than in the shorter roots or in the proximal regions of the sciatic nerve which are also affected to some extent. Amyelination does not appear to be a consequence of myelin or Schwann cell degeneration, as debris is uncommon. Heterozygous carriers are not affected in any obvious way. Myelinated fibres, with Schwann cells of peripheral origin, occur immediately adjacent to the spinal cord in both dorsal and ventral roots, while in dorsal roots unmyelinated fibres also occur, as in normal animals. Amyelinated fibres begin to appear a few internodal lengths away from the cord and are present until near, or within, the dorsal root ganglion, where they become myelinated again. The portion of an axon which has no myelin begins at a normal appearing paranodal region (termed a half node of Ranvier) at the end of a myelin internode. Resumption of myelination likewise begins at a half node. A few myelinated axons may be seen in any given cross section of a root, but as a rule a given myelinated fibre does not remain myelinated throughout the whole length of the root. It is suggested that the nerve lesions develop where the nerves are lengthening rapidly as the animal grows and changes its shape. How these nerve changes release to those in muscle is conjectural.

摘要

在129/ReJ和C57Bl/6J两种表型的营养不良型dy/dy小鼠中,颈、胸、腰和骶段的背侧和腹侧脊髓神经根的大多数神经纤维周围完全缺乏任何类型的施万细胞鞘。这种情况被称为无髓鞘形成,在较长的腰段和骶段神经根中比在较短的神经根或坐骨神经近端区域更为广泛(长度可达1 - 5厘米),坐骨神经近端区域也受到一定程度的影响。无髓鞘形成似乎不是髓鞘或施万细胞变性的结果,因为碎片并不常见。杂合子携带者没有受到任何明显影响。有外周来源施万细胞的有髓纤维紧邻脊髓出现在背根和腹根中,而在背根中也有无髓纤维,这与正常动物一样。无髓鞘纤维从离脊髓几个节间长度处开始出现,并一直存在到接近或在背根神经节内,在那里它们再次形成髓鞘。轴突没有髓鞘的部分从髓鞘节间末端一个外观正常的结旁区域(称为朗飞半结)开始。髓鞘形成的恢复同样从一个半结开始。在神经根的任何给定横切面上都可以看到一些有髓轴突,但通常给定的有髓纤维在神经根的整个长度上并不一直保持有髓状态。有人认为,神经病变发生在随着动物生长和体型变化神经快速延长的部位。这些神经变化如何导致肌肉中的变化尚属推测。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6f80/1231626/6c5c01c8939b/janat00378-0172-b.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6f80/1231626/3f6549f63a5e/janat00378-0174-a.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6f80/1231626/c8dd830119a3/janat00378-0174-b.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6f80/1231626/3c7fad5090a5/janat00378-0174-c.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6f80/1231626/794c6cd38d22/janat00378-0176-a.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6f80/1231626/b96dd1b4a47f/janat00378-0176-b.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6f80/1231626/620c91ffb48a/janat00378-0178-a.jpg
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